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CN107792606B - Article conveying apparatus - Google Patents

Article conveying apparatus Download PDF

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Publication number
CN107792606B
CN107792606B CN201710720263.3A CN201710720263A CN107792606B CN 107792606 B CN107792606 B CN 107792606B CN 201710720263 A CN201710720263 A CN 201710720263A CN 107792606 B CN107792606 B CN 107792606B
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CN
China
Prior art keywords
vehicle
article transport
article
track
transport vehicle
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Active
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CN201710720263.3A
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Chinese (zh)
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CN107792606A (en
Inventor
高川夏生
加藤俊和
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Daifuku Co Ltd
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Daifuku Co Ltd
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Publication of CN107792606A publication Critical patent/CN107792606A/en
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65GTRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
    • B65G35/00Mechanical conveyors not otherwise provided for
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65GTRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
    • B65G1/00Storing articles, individually or in orderly arrangement, in warehouses or magazines
    • B65G1/02Storage devices
    • B65G1/04Storage devices mechanical
    • B65G1/0492Storage devices mechanical with cars adapted to travel in storage aisles
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05BCONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
    • G05B19/00Programme-control systems
    • G05B19/02Programme-control systems electric
    • G05B19/418Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control [DNC], flexible manufacturing systems [FMS], integrated manufacturing systems [IMS] or computer integrated manufacturing [CIM]
    • G05B19/4189Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control [DNC], flexible manufacturing systems [FMS], integrated manufacturing systems [IMS] or computer integrated manufacturing [CIM] characterised by the transport system
    • G05B19/41895Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control [DNC], flexible manufacturing systems [FMS], integrated manufacturing systems [IMS] or computer integrated manufacturing [CIM] characterised by the transport system using automatic guided vehicles [AGV]
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05DSYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
    • G05D1/00Control of position, course, altitude or attitude of land, water, air or space vehicles, e.g. using automatic pilots
    • G05D1/02Control of position or course in two dimensions
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65GTRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
    • B65G2203/00Indexing code relating to control or detection of the articles or the load carriers during conveying
    • B65G2203/02Control or detection
    • B65G2203/0266Control or detection relating to the load carrier(s)
    • B65G2203/0283Position of the load carrier
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65GTRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
    • B65G2811/00Indexing codes relating to common features for more than one conveyor kind or type
    • B65G2811/06Devices controlling the relative position of articles
    • B65G2811/0673Control of conveying operations
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B65CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
    • B65GTRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
    • B65G2811/00Indexing codes relating to common features for more than one conveyor kind or type
    • B65G2811/09Driving means for the conveyors
    • B65G2811/091Driving means for the conveyors the conveyor type being irrelevant
    • B65G2811/093Control means for automatic stop, start or warning variation during conveying operations
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P90/00Enabling technologies with a potential contribution to greenhouse gas [GHG] emissions mitigation
    • Y02P90/02Total factory control, e.g. smart factories, flexible manufacturing systems [FMS] or integrated manufacturing systems [IMS]
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P90/00Enabling technologies with a potential contribution to greenhouse gas [GHG] emissions mitigation
    • Y02P90/60Electric or hybrid propulsion means for production processes

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  • Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Automation & Control Theory (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Manufacturing & Machinery (AREA)
  • Quality & Reliability (AREA)
  • Aviation & Aerospace Engineering (AREA)
  • Radar, Positioning & Navigation (AREA)
  • Remote Sensing (AREA)
  • Control Of Position, Course, Altitude, Or Attitude Of Moving Bodies (AREA)

Abstract

The object conveying equipment of the invention can properly detect the position of each object conveying vehicle even if the track for a plurality of object conveying vehicles to travel contains a curve section, thereby inhibiting the object conveying vehicles from contacting each other. A position detection device (7) detects absolute coordinates of the article transport vehicle (3) on the basis of marks at a plurality of positions along the extension direction of the track including the curved section, and supplies position information including information of the absolute coordinates to at least another article transport vehicle (3) via a wireless network (50). A transport vehicle control unit (5) that causes an article transport vehicle (3) to travel at least from a transport origin to a transport destination of an article in accordance with an instruction from a management device (1) reduces the travel speed of the article transport vehicle (3) when the separation distance between the vehicle and another vehicle is within a predetermined set separation distance in accordance with the position information of the vehicle and the position information of the other vehicle.

Description

Article conveying apparatus
Technical Field
The present invention relates to an article transport facility including a plurality of article transport vehicles that travel on a track provided via a plurality of article transfer positions.
Background
An example of an article transport facility including a plurality of article transport vehicles (3) that travel on rails (2) and transfer articles to a plurality of article transfer locations is disclosed in japanese patent No. 4232112 (patent document 1) (in the background art, the reference numerals in parentheses are those of the referenced documents). The track (2) of the article transport facility exemplified in this document is linear and has an end type defining both ends. The article transport vehicle (3) is further provided with 2 stations (3 a, 3 b). The article transport facility is provided with 1 ground controller (14) for controlling the travel of 2 article transport vehicles (3 (3 a, 3 b)). The ground controller (14) communicates with each article transport vehicle (3 (3 a, 3 b)) using an optical transmission device (16, 17). Optical position detection sensors (15) are provided at both ends of the track (2), respectively, and the position detection sensors (15) detect the distance from each end of the track (2) to the article transport vehicle (3) present on the side close to the end, thereby detecting the position of each article transport vehicle (3 a, 3 b)) on the track (2). The detection information of the position detection sensor (15) is input to the ground controller (14). The ground controller (14) manages the operation of the article transport vehicles (3 a, 3 b)) on the track (2) on the basis of the detection information of the position detection sensor (15).
In this way, when the track (2) is linear, the ground controller (14) can control the article transport vehicles (3) so that the article transport vehicles (3) do not contact each other, based on the positions of the article transport vehicles (3) detected by the detection sensors (15) provided at both ends of the track (2). However, in the case where the track (2) has a curve, since a dead space is generated in the detection area of the position detection sensor (15), a configuration in which the position detection sensors (15) are provided only at both ends of the track (2) is insufficient for appropriate control. Japanese patent No. 4340976 (patent document 2) discloses an article transport facility in which a track (K) on which an article transport vehicle (3) travels has a curve. The track (K) is composed of 2 straight sections (L1, L2) and a curved section (R) between them. In the article transport device, optical position detection sensors (15) are disposed at both ends of a track (K) and outside a curve, and the positions of article transport vehicles (3) in linear sections (L1, L2) are detected so as to partially include a curve section (R). Further, contact between the article transport vehicles (3) is suppressed by exclusively controlling the article transport vehicles (3) that can enter the curved section (R).
[ Prior art documents ]
[ patent document ]
[ patent document 1 ] Japanese patent No. 4232112
[ patent document 2 ] Japanese patent No. 4340976
Disclosure of Invention
[ problem to be solved by the invention ]
In view of the above-described background, it is desirable in the industry to appropriately detect the position of each article transport vehicle and suppress contact between the article transport vehicles even when a curved section is included in a track on which a plurality of article transport vehicles travel.
[ MEANS FOR SOLVING PROBLEMS ] A method for producing a semiconductor device
In view of the above, an article transport facility according to 1 aspect includes: a plurality of article transport vehicles that travel on a track provided via a plurality of article transfer positions; a position detecting device that detects a position of each of the article transport vehicles on the track; and a management device for controlling the operation of each of the article transport vehicles based on the position information detected by the position detection device, the article transport facility being characterized in that,
the article transport vehicle includes a transport vehicle control unit that causes the article transport vehicle to travel at least from a transport start point to a transport destination of an article in accordance with an instruction from the management device,
the track comprising a curved section and having marks representing absolute positions on the track at a plurality of positions along the extension of the track,
the position detection device is provided on each of the article transport vehicles, detects an absolute coordinate of each of the article transport vehicles on the track based on the marker, and provides the position information including information of the absolute coordinate to at least another article transport vehicle via a wireless network,
the transport vehicle control unit reduces the travel speed of the article transport vehicle when a separation distance between the article transport vehicles along the track is within a predetermined set separation distance based on the position information of the own vehicle and the position information of the other vehicle.
Here, the absolute position refers to information of a position on the track, and the absolute position is information having a resolution according to the arrangement density of the marks arranged at a plurality of positions. The set density is a density at least corresponding to the interval of the marks provided in the extending direction of the track. The absolute coordinates are information of the position of the article transport vehicle on the track, and are defined based on the absolute position, and theoretically, information of which resolution is not set to a limit. However, in terms of practicality, the performance of the position detection device (for example, the resolution of detecting the marker) is limited, and therefore, the resolution of the absolute coordinates is determined according to the performance (resolution) of the position detection device. The absolute coordinates have a resolution at least higher than the resolution of the absolute position.
In the above configuration, the position information including the absolute coordinates detected by the position detection device mounted on the article transport vehicle is also supplied to the other article transport vehicle via the wireless network. Therefore, each article transport vehicle can appropriately control the travel of the vehicle on the track using the position information of the vehicle and the other vehicles. The position detection device detects the absolute coordinates of the article transport vehicle based on markers arranged at a plurality of positions in the extending direction of the rail, not by measuring the distance from the end of the rail to the article transport vehicle. Therefore, even if the track includes a curved section, the position detection device can detect the absolute coordinates of the article transport vehicle by the same method in all the sections of the track, and the transport vehicle control unit can cause the article transport vehicle to travel in the curved section without involving exclusive processing or the like. The transport vehicle control unit may calculate the inter-vehicle distance, i.e., the separation distance, between the host vehicle and the other vehicle based on the position information of the host vehicle and the position information of the other vehicle. That is, the travel speed of the host vehicle can be controlled according to the separation distance, and contact between the host vehicle and another vehicle can be suppressed. That is, according to the present configuration, even when the curved section is included in the track on which the plurality of article transport vehicles travel, the position of each article transport vehicle can be appropriately detected, and contact between the article transport vehicles can be suppressed.
Here, it is preferable that the plurality of article transport vehicles communicate with each other via the same wireless network, and each of the plurality of article transport vehicles communicates with the management device.
With this configuration, the management device and each article transport vehicle can easily share information via the same wireless network. Therefore, for example, by sharing the position information of the article transport vehicle, it is possible to suppress contact between the article transport vehicles in the control of the operation of the article transport vehicle by the management device, and to suppress contact between the other article transport vehicles for each article transport vehicle. That is, the article transport vehicles can be suppressed from contacting each other by various methods.
Here, as 1 mode, it is preferable that the track of the article carrying facility is of an end type in which both end portions are defined.
For example, in the case where the track is an endless track, the article transport vehicle can be made to travel in one direction, whereas in the case where the track is an endless track, the article transport vehicle having reached the end does not travel to the destination in one direction, and therefore the travel mode must be made to travel in two directions. Further, on the track capable of bidirectional passage, there are cases where 2 article transport vehicles travel in the approaching direction. When the passage method is the one-way passage, the relative speed of the 2 article transport vehicles is a speed obtained by subtracting the traveling speed of the article transport vehicle in front from the traveling speed of the article transport vehicle behind in the traveling direction. That is, the maximum relative speed is only the traveling speed of the rear article transport vehicle (when the front article transport vehicle is stopped). On the other hand, when 2 article transport vehicles approach in the bidirectional passage, the relative speed is the sum of the traveling speeds of the 2 article transport vehicles. That is, the lowest relative speed when the 2 article transport vehicles approach each other is the traveling speed of one article transport vehicle (the other article transport vehicle is extremely low, for example, almost stopped).
That is, in the two-way passable track, 2 article transport vehicles approach faster than the one-way passable track. Therefore, when the article transport vehicle travels on a track that can pass in both directions, it is preferable to mutually and quickly acquire the position information of other vehicles. For example, it is also conceivable to mount a sensor (e.g., an optical obstacle sensor such as a laser radar) for directly detecting a distance to another vehicle on each article transport vehicle, and an optical communication device for transmitting a message for calling attention or a warning message to another vehicle based on a detection result (e.g., the optical transmission devices (16, 17) of japanese patent No. 4232112 (patent document 1)). However, in many cases, this type of apparatus uses an optical principle, and is effective when the trajectory is a straight line, but when the trajectory includes a curved section, there is a possibility that a dead angle is generated. Further, even when the track is a straight line, the detection range and the communicable range are limited, and therefore, there is a possibility that the time for starting the detection of the approach of another vehicle or the processing of the approach is delayed. Further, as described above, in the track capable of two-way passage, since 2 article transport vehicles approach faster than the track capable of one-way passage, it is necessary to detect the approach of another vehicle earlier.
According to this configuration, even if the track includes a curved section, the position detection device of each article transport vehicle can detect the absolute coordinates of the article transport vehicle by the same method in all the sections of the track. Thus, the transport vehicle control unit of each article transport vehicle can cause the article transport vehicle to travel within the curved section without involving exclusive processing or the like. Further, the transport vehicle control unit can control the traveling speed of the host vehicle based on the position information of the host vehicle and the position information of the other vehicle, and can suppress contact between the host vehicle and the other vehicle. In particular, in the case where the track of the article transport facility is of the end type in which both end portions are defined, the above-described problem occurs, but even in such a case, the contact between the article transport vehicles can be appropriately suppressed. In other words, the present configuration is particularly useful when the track of the article transport facility is of an end type in which both end portions are defined.
In addition, as the 1 mode, it is preferable that the transport vehicle control unit decreases the traveling speed of the own vehicle when the separation distance from the other vehicle as the article transport vehicle existing in the traveling direction of the own vehicle is within the set separation distance.
When there is another vehicle in the traveling direction of the host vehicle and the distance from the host vehicle is within the set distance, the host vehicle may come into contact with the other vehicle. Here, if the traveling speed of the host vehicle is reduced, the separation distance is increased, and therefore, contact between the host vehicle and another vehicle can be suppressed. When another vehicle is present behind the host vehicle (in the opposite direction to the traveling direction) and the distance from the host vehicle is within the set distance, if the traveling speed of the host vehicle is reduced, the distance is further shortened, which is not preferable. Therefore, in this case, it is preferable that the other vehicle side lowers the traveling speed. In view of the other vehicle, the own vehicle becomes an article transport vehicle existing in the traveling direction of the other vehicle, and therefore the other vehicle reduces the traveling speed of the other vehicle according to the distance from the article transport vehicle existing in the traveling direction of the other vehicle.
In addition, as the 1 st aspect, it is preferable that the transport vehicle control unit stops the own vehicle when the separation distance is within a limit distance set shorter than the set separation distance.
Even if the traveling speed of the host vehicle is reduced, the distance from the other vehicle existing in the traveling direction of the host vehicle may be gradually reduced in relation to the traveling speed of the other vehicle, and the host vehicle may come into contact with the other vehicle at some distance. If the shortening of the separation distance is suppressed by stopping the host vehicle, it is possible to reduce the risk of the host vehicle coming into contact with another vehicle. Since the separation distance may be short even if the traveling speed of the host vehicle is reduced and the host vehicle may come into contact with another vehicle, the transport vehicle control unit preferably stops the host vehicle when the separation distance is within a limit distance set to be shorter than the set separation distance.
In addition, as 1 mode, it is preferable that the position detection device also supplies the position information to the management device via the wireless network, and the management device controls the operation of each of the article transport vehicles in accordance with a position where each of the article transport vehicles exists.
In many article transport facilities, a management device is provided that integrates a plurality of article transport vehicles and controls the operation of the vehicle. Since the position information of each article transport vehicle is placed on the wireless network, the management device can appropriately acquire the position information of all the article transport vehicles via the wireless network without acquiring the position information from the article transport vehicles by other communication means or connection means. Thus, the configuration of the article transport apparatus can be simplified. The connection between the management device and the wireless network may be wireless or wired, and may be in a form in which the management device is connected to the wireless network used by the article transport vehicle.
In addition, as 1 mode, it is preferable that the marker includes a one-dimensional or two-dimensional barcode indicating at least the absolute position, and the position detection device includes: a camera that photographs the mark; and an image processing unit that detects the absolute coordinates of the article transport vehicle by recognizing the information of the absolute position indicated by the marker from a captured image obtained by the camera.
The position detection device can calculate the relationship between the position of the camera and the absolute position indicated by the marker from the relationship between the position of the camera in a so-called world coordinate system (real three-dimensional coordinate system) and a camera coordinate system projected on a captured image of the camera. That is, the absolute position indicated by the marker can be applied to the coordinates of the camera coordinate system in the captured image, and the absolute coordinates of the camera (for example, the origin of the camera coordinate system) can be calculated from the relationship with the absolute position. Of course, the resolution of the position of the camera in the coordinate system of the captured image is higher than the resolution of the position of the marker on the track, and therefore, absolute coordinates with high accuracy with respect to the absolute position can be obtained.
Further features and advantages of the article transport apparatus will be apparent from the following description of the embodiments described with reference to the drawings.
Drawings
Fig. 1 is a top view of an article transport apparatus.
Fig. 2 is a block diagram schematically showing the configuration of the article transport facility.
Fig. 3 is an explanatory diagram schematically showing the principle of position detection by the position detection device.
Fig. 4 is an explanatory diagram schematically showing a relationship between an absolute position and an absolute coordinate.
Fig. 5 is an explanatory diagram schematically illustrating the detection principle of the inter-vehicle distance sensor.
Fig. 6 is a flowchart showing an example of speed control of the article transport vehicle.
Fig. 7 is a plan view showing another configuration example of the article transport apparatus.
Detailed Description
Next, an embodiment of the article transport apparatus 100 will be described with reference to the drawings. As shown in fig. 1, the article transport facility 100 includes a plurality of article transport vehicles 3 that travel on rails K provided via a plurality of stations 10 (article transfer positions). The track K shown in fig. 1 has a straight section L and a curved section R, and is an end type in which both ends are defined. The article transport vehicle 3 reciprocates on the track K, and transports the article B between the plurality of stations 10. In the present embodiment, the track K is formed by disposing a pair of running rails 2 as a running path on the ground. The stations 10 are disposed on both sides in the width direction S of the running guide 2 in the linear section L (width direction S: a direction perpendicular to the extending direction T along the horizontal plane) at intervals in the extending direction T of the running guide 2.
The station 10 includes a plurality of stations such as a station for delivery provided with a delivery conveyor for conveying an article B delivered from an article storage rack, not shown, a station for storage provided with a delivery conveyor for conveying an article B delivered to the article storage rack, a station for loading provided with a delivery conveyor for conveying an article B delivered from the outside to the article storage rack, and a station for unloading provided with a delivery conveyor for conveying an article B delivered to the outside. For example, one of the plurality of stations 10 serves as a transport origin and the other serves as a transport destination. When the article transport vehicle 3 travels to the transport departure point, the transport departure point is the target travel position of the article transport vehicle 3, and when the article transport vehicle 3 travels to the transport destination, the transport destination is the target travel position of the article transport vehicle 3.
As shown in fig. 2, the article transport vehicle 3 is provided with a transfer device 34 such as a roller conveyor for transferring the article B between the vehicle (article transport vehicle 3) and the station 10, and a plurality of wheels 35 that run on the running rail 2. The transfer device 34 is driven by a transfer driving unit 36. The transfer drive unit 36 includes an actuator such as a motor for driving the roller conveyor, a drive circuit including an inverter circuit for driving the actuator, and the like. The wheels 35 include driving wheels driven by the traveling drive unit 37 and driven wheels. Preferably, the drive wheels are disposed on the inner side and the driven wheels are disposed on the outer side of the article transport vehicle 3 when the vehicle travels within the curved section R of the travel rail 2. The driving unit 37 for running includes a motor for running that applies a turning force to the wheels 35, a driving circuit including an inverter circuit that drives the motor for running, and the like.
The article transport vehicle 3 further includes a transport vehicle control unit 5, a position detection device 7, an inter-vehicle distance sensor 8, a communication control unit 9, and a communication antenna 91. The transport vehicle control unit 5 causes the article transport vehicle 3 to travel at least from the transport start point to the transport destination of the article B in response to an instruction from the management device 1 described below, and causes the transport vehicle 3 to transfer the article B to the transport start point and the transport destination. That is, the transport vehicle control unit 5 drives the wheels 35 via the travel drive unit 37, and drives the transfer device 34 via the transfer drive unit 36. The position detection device 7 detects the position of each article transport vehicle 3 on the track K. In the present embodiment, the position detection device 7 detects absolute coordinates of the article transport vehicle 3 on the track K, which will be described in detail later. The inter-vehicle distance sensor 8 projects measurement light in the traveling direction (front-rear direction) of the article transport vehicle 3 to detect the distance to the adjacent article transport vehicle 3. The communication control unit 9 and the communication antenna 91 supply the position information (the position information of the article transport vehicle 3) including the information of the absolute coordinates to at least the other article transport vehicle 3 via the network 50. In the present embodiment, the communication control unit 9 and the communication antenna 91 support wireless communication (for example, wireless LAN), and the network 50 is a wireless network. The network 50 may be a type in which a plurality of different networks are connected. For example, a wireless network and a wired network may be connected to form the network 50. The network 50 may include a network of a connection type in which the article transport vehicles 3 directly communicate with each other.
As shown in fig. 2, the article transport facility 100 is provided with a management device 1, and the management device 1 controls the respective operations of the article transport vehicles 3 based on the position information detected by the position detection device 7. The management device 1 is also connected to the network 50, and acquires position information (position information of the article transport vehicle 3) including the information of the absolute coordinates via the network 50. That is, the position detection device 7 also provides the management device 1 with position information via the network 50, and the management device 1 controls the operation of each of the article transport vehicles 3 according to the position where each of the article transport vehicles 3 exists. As described above, since the position information of each article transport vehicle is placed on the network 50, the management device 1 can appropriately acquire the position information of all the article transport vehicles 3 via the network 50 without acquiring the position information from the article transport vehicles 3 by other communication means or connection means. The connection between the management device and the network 50 may be wireless or wired, and may be in a form in which the management device 1 is connected to the network 50 (wireless network) used by the article transport vehicle 3. Fig. 2 illustrates a form in which the network 50 and the management apparatus 1 are wired.
The management device 1 specifies an article transport vehicle 3 closer to the transport departure point based on the position information of each article transport vehicle 3, for example, and issues a transport command for the article B. The transport vehicle control unit 5 controls the travel drive unit 37 and the transfer drive unit 36 in accordance with the transport command, and causes the article transport vehicle 3 to transfer and transport the article B. The article transport vehicle 3 preferably travels (autonomously travels) under autonomous control of the transport vehicle control unit 5 to transfer the article B. In order to realize such autonomous control, for example, various sensors such as an unillustrated article presence sensor for detecting the presence of the article B on the transfer device 34 may be provided on the article transport vehicle 3. Further, since the plurality of article transport vehicles 3 are disposed on the track K, the transport vehicle control unit 5 must grasp the positions of the own vehicle and the other vehicles in order to appropriately perform autonomous traveling. Therefore, the article transport vehicle 3 includes the position detection device 7. The position detection device 7 mounted on each article transport vehicle 3 detects the absolute coordinates of each article transport vehicle 3 on the track K based on the markers 20 provided along the track K. On the track K including the curve section R, markers 20 indicating absolute positions on the track K are provided at a plurality of positions. Preferably, a plurality of marks 20 are arranged along the track K as shown in fig. 3. In the present embodiment, the marker 20 is exemplified as a two-dimensional barcode. However, the present invention is not limited to this form, and may be a one-dimensional bar code, a plate on which characters or numbers are recorded, or the like.
Here, the absolute position (hereinafter referred to as "P" with reference to fig. 3 and 4) is information of a position on the track K, and the absolute position P is information having a resolution corresponding to the arrangement density of the marks 20 arranged at a plurality of positions. The set density is a density at least corresponding to the interval in which the marks 20 are provided in the extending direction T of the track K. The absolute coordinate (hereinafter referred to as "Q" with reference to fig. 4) is information on the position of the article transport vehicle 3 on the track K, and the absolute coordinate Q is defined based on the absolute position P and theoretically is information on which the resolution is not set to a limit. However, in terms of practicality, the performance of the position detection device 7 (for example, the resolution of detecting the marker 20) is limited, and therefore the resolution of the absolute coordinate Q is determined according to the performance of the position detection device 7. Here, the performance in the present embodiment refers to, for example, the resolution of the camera 73 and the resolution of a captured image obtained by the camera 73, which will be described later. Thus, the absolute coordinate Q has a resolution at least higher than that of the absolute position P.
The position detection device 7 includes a camera 73 for capturing the mark 20 and an image processing unit 71. The image processing unit 71 recognizes the information of the absolute position P indicated by the marker 20 from the captured image obtained by the camera 73, and detects the absolute coordinate Q of the article transport vehicle 3. As shown in fig. 3, the size and the arrangement position of each marker 20 are set so that, for example, 6 markers 20 can be captured in the captured image (imaging area E) of the camera 73. The image processing unit 71 performs image processing on the two-dimensional barcode included in the captured image of the camera 73, thereby recognizing information on the absolute position indicated by the marker 20 (two-dimensional barcode) (image processing). The same applies to the case where the mark 20 is a one-dimensional barcode or characters or numbers. For example, in the case of letters or numbers, information of absolute positions can be recognized by performing letter Recognition (OCR).
The position detection device 7 can calculate the relationship between the position of the camera 73 and the absolute position indicated by the marker 20 from the relationship between the position of the camera 73 in a so-called world coordinate system (real three-dimensional coordinate system) and the camera coordinate system projected on the captured image of the camera 73. That is, the absolute position indicated by the marker 20 can be applied to the coordinates of the camera coordinate system in the captured image, and the absolute coordinates of the camera 73 (the origin of the camera coordinate system in this case) can be calculated from the relationship with the absolute position. As shown in fig. 3, the absolute coordinates can be obtained as coordinates of a 3-dimensional orthogonal coordinate system having an X axis, a Y axis, and a Z axis.
However, in the present embodiment, since the marker 20 is disposed at a predetermined position on the travel rail 2 and the article transport vehicle 3 having the camera 73 mounted thereon also travels on the travel rail 2, the Y axis and the Z axis may be substantially fixed. Of course, the Y-axis and Z-axis coordinates may also vary due to individual differences, strain, aging deterioration of the travel rail 2 or the wheels 35, vertical displacement of the article transport vehicle 3 caused by whether or not the article B is mounted, an error in the mounting position of the marker 20 on the travel rail 2, and the like. In this case, it is of course preferable to correct the Y-axis and Z-axis coordinates based on the image recognition result.
Fig. 4 illustrates the concept of finding the absolute position P on the track K indicated by the marker 20 and the absolute coordinate Q (camera 73) of the article transport vehicle 3, as represented by the X axis only. For example, in the case where the photographing region E is "E1" shown in fig. 3, as shown in fig. 4, the absolute coordinates "Q1" are derived from the absolute positions "P1" and "P2". Further, in the case where the photographing region E is "E2" shown in fig. 3, as shown in fig. 4, the absolute coordinates "Q2" are derived from the absolute positions "P3" and "P4".
As described above, the plurality of article transport vehicles 3 are arranged on the track K. The management device 1 controls the operation by outputting a transport command so that the article transport vehicles 3 do not contact each other on the track K, but each article transport vehicle 3 that has received the transport command operates (travels and transfers) by autonomous control. For example, depending on the placement state of the article B on each station 10, it may take longer than the standard transfer time to transfer the article B. Further, there is a case where the article transport vehicle 3 is decelerated due to the occurrence of an obstacle or the like on the track K, and the article transport vehicle 3 travels for a time longer than the standard travel time. If such a phenomenon occurs, the article transport vehicles 3 may come into contact with each other at a position where the management device 1 is not supposed.
In the present embodiment, such contact can be suppressed by the autonomous control of the conveyance vehicle control unit 5. As described above, the position detection device 7 is provided in each article transport vehicle 3. The detected position information is provided to at least the other article transport vehicle 3 via the network 50. As will be described later with reference to the flowchart of fig. 6, the transport vehicle control unit 5 decreases the traveling speed V of the article transport vehicle 3 (own vehicle) (# 3 → # 4) when the separation distance D between the article transport vehicles along the track K is within a predetermined set separation distance D1 based on the position information of the own vehicle and the position information of the other vehicles. This suppresses the contact between the host vehicle and another vehicle. When the separation distance D exceeds the set separation distance D1, the traveling speed V of the article transport vehicle 3 (the own vehicle) is returned to the standard traveling speed.
Of course, even if the separation distance D from the other vehicle on the opposite side of the traveling direction of the own vehicle is equal to or less than the set separation distance D1, the own vehicle does not collide with the other vehicle from behind. Therefore, it is preferable that the transport vehicle control unit 5 decrease the traveling speed V of the own vehicle when the separation distance D between the own vehicle and another vehicle as the article transport vehicle 3 existing in the traveling direction of the own vehicle is within the set separation distance D1. It is preferable that a limit distance D2 shorter than the set separation distance D1 is further set, and when the separation distance D is within the limit distance D2, the transport vehicle control unit 5 stops the vehicle (# 2 → # 5).
As described above, the article transport vehicle 3 is mounted with the inter-vehicle distance sensor 8. Considering that communication via the network 50 requires a certain time, it is preferable to also implement control using the detection result of the inter-vehicle distance sensor 8 as fail-safe. As schematically shown in fig. 5, the inter-vehicle distance sensor 8 detects an inter-vehicle distance M between the own vehicle as the rear vehicle 3a and another vehicle (the front vehicle 3 b) present in the traveling direction of the own vehicle. Although not shown in the drawings, in the present embodiment, since the article transport vehicle 3 travels on the track K in both directions, the inter-vehicle distance sensors 8 are provided on both the front and rear sides. Although not shown in the drawing, the inter-vehicle distance sensor 8 is also provided in the front vehicle 3 b. When the inter-vehicle distance M detected by the inter-vehicle distance sensor 8 is equal to or less than a predetermined lower limit inter-vehicle distance M1, the transport vehicle control unit 5 stops the host vehicle (the rear vehicle 3 a) (# 1 → # 5). The lower limit inter-vehicle distance M1 is set to a length shorter than the limit distance D2.
Next, the speed control of the article transport vehicle 3 by the transport vehicle control unit 5 will be described with reference to the flowchart of fig. 6. In the present embodiment, the transport vehicle control unit 5 of the rear vehicle 3a (the own vehicle) determines the separation distance D (and the inter-vehicle distance M) from the front vehicle 3b in 3 stages (# 1, #2, # 3). In step #1, it is determined whether the inter-vehicle distance M detected by the inter-vehicle distance sensor 8 is equal to or less than the lower limit inter-vehicle distance M1. When "M is equal to or less than M1", the transport vehicle control unit 5 stops the article transport vehicle 3 by controlling the travel speed V of the article transport vehicle 3 to be zero as described above (# 5).
When it is determined in step #1 that the inter-vehicle distance M is greater than the lower limit inter-vehicle distance M1, it is next determined in step #2 whether or not the separation distance D is equal to or less than the limit distance D2. When "D ≦ D2", the transport vehicle control unit 5 controls the article transport vehicle 3 to stop (# 5) so that the traveling speed V of the article transport vehicle 3 becomes zero as described above.
If it is determined in step #2 that the separation distance D is greater than the limit distance D2, it is next determined in step #3 whether or not the separation distance D is equal to or less than the set separation distance D1. If "D ≦ D1", the transport vehicle control unit 5 decreases the traveling speed V of the article transport vehicle 3 to the slow traveling speed Vslow (# 4) as described above. The slow speed Vslow is a low speed that is much lower than the speed at which the article transport vehicle 3 normally travels, and is preferably as follows: when the transport vehicle control unit 5 issues a stop command, the article transport vehicle 3 can stop traveling within a predetermined stop time or a predetermined stop distance.
Further, if the article transport vehicle 3 travels only in one direction on the track K, the travel destination of the article transport vehicle 3 that has reached the end portion does not exist when the track K is of the end type, and therefore the traffic method must be a bidirectional traffic capable of bidirectional travel. Further, on the track K capable of bidirectional passage, there are cases where 2 article transport vehicles 3 travel in the approaching direction. When the traffic mode is one-way traffic, the relative speed of the 2 article transport vehicles 3 is obtained by subtracting the traveling speed of the article transport vehicle 3 (3 b) ahead from the traveling speed of the article transport vehicle 3 (3 a) behind in the traveling direction. That is, the maximum relative speed is only the traveling speed of the rear article transport vehicle 3 (3 a) (when the front article transport vehicle 3 (3 b) is stopped). On the other hand, when 2 article transport vehicles 3 approach in the bidirectional passage, the relative speed is the sum of the traveling speeds of the 2 article transport vehicles 3. That is, the relative speed when the 2 article transport vehicles 3 approach each other is the traveling speed of one article transport vehicle 3 at the lowest (in the case where another article transport vehicle 3 travels at an extremely low speed or is almost stopped).
That is, in the track K capable of two-way passage, the 2 article transport vehicles 3 approach faster than the track K capable of one-way passage. Therefore, when the article transport vehicle 3 travels on the track K that can pass in both directions, it is preferable to mutually acquire the position information of other vehicles quickly. For example, it is also conceivable to mount a sensor (for example, the inter-vehicle distance sensor 8 described above with reference to fig. 5, an optical obstacle sensor such as a laser radar) for directly detecting the distance to another vehicle on each article transport vehicle 3, and an optical communication device (for example, the optical transmission devices (16, 17) of japanese patent No. 4232112 (patent document 1)) for transmitting a message of calling attention or a warning message to another vehicle based on the detection result.
However, in many cases, this type of apparatus uses an optical principle, and is effective when the track K is a straight line, but may generate a blind spot when the curved section R is included in the track K. Further, even if the track K is a straight line, the detection range and the communicable range are limited, and therefore, there is a possibility that the time for starting the detection of the approach of another vehicle or the processing of the approach is delayed. Further, as described above, in the track K capable of two-way passage, since the 2 article transport vehicles 3 approach faster than the track K capable of one-way passage, it is necessary to detect the approach of another vehicle earlier.
In the present embodiment, even if the track K includes the curved section R, the position detection device 7 of each article transport vehicle 3 can detect the absolute coordinates of the article transport vehicle 3 by the same method in all the sections of the track K. Thus, the transport vehicle control unit 5 of each article transport vehicle 3 can cause the article transport vehicle 3 to travel within the curved section R without involving exclusive processing or the like. Further, the transport vehicle control unit 5 can control the traveling speed of the host vehicle based on the position information of the host vehicle and the position information of the other vehicle, and can suppress contact between the host vehicle and the other vehicle. In particular, even in the case where the track K of the article transport facility 100 is of the end type in which both end portions are defined, the above-described problem occurs, but even in such a case, the contact between the article transport vehicles 3 can be appropriately suppressed. In other words, the configuration of the present embodiment is particularly useful when the track K of the article transport facility 100 is of an end type in which both end portions are defined.
In the present embodiment, as described above, the position detection device 7 provided in each article transport vehicle 3 detects the absolute coordinates of each article transport vehicle 3, and provides position information including information on the absolute coordinates via the wireless network. Further, the transport vehicle control unit 5 provided in each article transport vehicle 3 reduces the travel speed of the article transport vehicle 3 when the distance between the article transport vehicles 3 along the track K is within the set distance, based on the position information of the own vehicle and the position information of the other vehicle. That is, in the present embodiment, for example, the 2 article transport vehicles 3 perform the above-described control as the own vehicle and the other vehicle. That is, the approach of the article transport vehicle 3 can be monitored doubly, and contact of the article transport vehicle 3 can be further suppressed. Further, since the hardware configuration and software of the article transport vehicle 3 can be generalized, the article transport vehicle 3 can be standardized. For example, when the article transport vehicle 3 is replaced or when the article transport vehicle 3 is added to the article transport facility 100, it is not necessary to prepare a vehicle corresponding to each vehicle, which is preferable in terms of efficiency and cost.
When 2 article transport vehicles 3 are traveling in the direction of approaching on the track K capable of bidirectional passage as described above, the two article transport vehicles 3 mutually detect another vehicle and control the traveling speed of the own vehicle. The reduction in the travel speed of the two article transport vehicles 3 can further suppress contact of the article transport vehicles 3, compared to the reduction in the travel speed of only one article transport vehicle 3.
[ other embodiments ]
Next, another embodiment will be described. The configurations of the embodiments described below are not limited to being used individually, and may be used in combination with the configurations of other embodiments as long as no contradiction occurs.
(1) In the above description, referring to fig. 1, the track K has a straight line section L and a curved line section R, and is an end type form in which both end portions are defined. However, as long as the track K of the article transport facility 100 includes the curved section R, the track K does not need to be an end type in which both ends are defined, and may be in a ring shape as illustrated in fig. 7. In fig. 1 and 7, the track K includes the straight section L, but the track K does not necessarily include the straight section L. The track K may include a curved section R, or may be entirely curved (circular, elliptical, curved with ends, etc.). Further, when the track K is annular, the article transport vehicle can return to the departure point by 1 round of travel, and therefore the travel direction of the article transport vehicle can be set to one-way traffic. However, even when the track K is annular, the passage method may be bidirectional passage in which the article transport vehicle 3 can travel in both directions.
(2) In the above description, the transport vehicle control unit 5 of the rear vehicle 3a (the own vehicle) has been illustrated as determining the separation distance D (and the inter-vehicle distance M) from the front vehicle 3b in 3 stages of step #1, step #2, and step #3, but the article transport vehicle 3 may not have the inter-vehicle distance sensor 8. In this case, the transport vehicle control unit 5 of the rear vehicle 3a (the own vehicle) may determine the distance D from the front vehicle 3b in 2 stages of step #2 and step #3 without performing step #1, and may control the traveling speed of the article transport vehicle 3. In the above description, 2 types of speed control are performed according to the separation distance D (# 4, # 5), but only 1 type of control for stopping the article transport vehicle 3 (# 2 → # 5) may be performed, for example.
(3) In the above description, the example in which the article transport facility 100 includes 2 article transport vehicles 3 has been described, but 3 or more article transport vehicles 3 may be provided. When the article transport vehicle 3 is 2, the control by the vehicle and the control by another vehicle can double the suppression of the contact of the vehicle with another vehicle. In the case of 3 vehicles, the triple suppression can be achieved by the control by the own vehicle, the control by one other vehicle in the other 2 vehicles, and the control by another other vehicle in the other 2 vehicles. Of course, the number of the article transport vehicles 3 may be 4 or more. That is, even if the number of the article transport vehicles 3 is 3 or more, control for suppressing contact between the article transport vehicles 3 does not become difficult, and contact can be appropriately suppressed by multiplexing.
Description of the symbols
1 management device
3 article transport vehicle
5 transport vehicle control part
7 position detection device
10 station (article moving position)
20 sign
50 network (Wireless network)
71 image processing unit
73 vidicon
100 article conveying apparatus
B article
D separation distance
D1 setting the separation distance
D2 limiting distance
K track
Absolute position of P
Absolute coordinate of Q
Interval of R curve
Direction of extension of T
V running speed.

Claims (8)

1. An article transport facility is provided with: a plurality of article transport vehicles that travel on a track provided via a plurality of article transfer positions; a position detecting device that detects a position of each of the article transport vehicles on the track; and a management device for controlling the operation of each of the article transport vehicles based on the position information detected by the position detection device, the article transport facility being characterized in that,
the article transport vehicle includes a transport vehicle control unit that causes the article transport vehicle to travel at least from a transport start point to a transport destination of an article in accordance with an instruction from the management device,
the track comprising a curved section and having marks representing absolute positions on the track at a plurality of positions along the extension of the track,
the position detection device is provided on each of the article transport vehicles, detects an absolute coordinate of each of the article transport vehicles on the track based on the marker, and provides the position information including information of the absolute coordinate to at least another article transport vehicle via a wireless network,
the resolution of the absolute coordinates is at least higher than the resolution of the absolute position,
each of the position detection devices has a camera for photographing the mark and an image processing section,
the image processing unit detects the absolute coordinates of the article transport vehicle by recognizing the information of the absolute position indicated by the marker from the captured image obtained by the camera,
the transport vehicle control unit calculates a separation distance, which is an inter-vehicle distance between the host vehicle and another vehicle, based on the position information of the host vehicle and the position information of the other vehicle, and reduces a traveling speed of the article transport vehicle when the separation distance between the article transport vehicles along the track is within a predetermined set separation distance.
2. The article transport facility according to claim 1, wherein a plurality of the article transport vehicles communicate with each other via the same wireless network, and each of the plurality of the article transport vehicles communicates with the management device.
3. The article transport apparatus according to claim 1, wherein the rail is of an end type defining both end portions.
4. The article transport facility according to claim 1, wherein the transport vehicle control unit decreases a traveling speed of the own vehicle when the separation distance between the own vehicle and another vehicle as the article transport vehicle existing in a traveling direction of the own vehicle is within the set separation distance.
5. The article transport facility according to claim 1, wherein the transport vehicle control unit stops the own vehicle when the separation distance is within a limit distance set shorter than the set separation distance.
6. The article transport facility according to claim 4, wherein the transport vehicle control unit stops the own vehicle when the separation distance is within a limit distance set shorter than the set separation distance.
7. The article transport apparatus according to any one of claims 1 to 6, wherein the position detection device also provides the position information to the management device via the wireless network, and the management device controls the respective operations of the article transport vehicles according to the positions where the respective article transport vehicles exist.
8. The article transport apparatus according to any one of claims 1 to 6, wherein the mark comprises a one-dimensional or two-dimensional barcode representing at least the absolute position,
the position detection device is provided with: a camera that photographs the mark; and an image processing unit that detects the absolute coordinates of the article transport vehicle by recognizing the information of the absolute position indicated by the marker from a captured image obtained by the camera.
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